TY - JOUR
T1 - Appraising widespread resprouting but variable levels of postfire seeding in Australian ecosystems
T2 - The effect of phylogeny, fire regime and productivity
AU - Lawes, Michael J.
AU - Crisp, Michael D.
AU - Clarke, Peter J.
AU - Murphy, Brett P.
AU - Midgley, Jeremy J.
AU - Russell-Smith, Jeremy
AU - Nano, Catherine E.M.
AU - Bradstock, Ross A.
AU - Enright, Neal J.
AU - Fontaine, Joseph B.
AU - Gosper, Carl R.
AU - Woolley, Leigh Ann
N1 - Publisher Copyright:
© 2022 The Author(s). Published by CSIRO Publishing.
PY - 2022/3
Y1 - 2022/3
N2 - Postfire resprouting (R+) and recruitment from seed (S+) are common resilience traits in Australian ecosystems. We classified 2696 woody Australian taxa as R+ or not (R-) and as S+ or not (S-). The proportions of these traits in Australian ecosystems were examined in relation to fire regimes and other ecological correlates, and by trait mapping on a phylogeny scaled to time. Resprouting mapped as an ancestral trait. Postfire reseeding recruitment, while ancient, is more taxonomically restricted and has evolved independently several times. Nevertheless, both R+ and S+ are common in most clades, but negatively correlated at the ecosystem level indicating an evolutionary trade-off related to differences in the severity of fire regimes, determined in part by ecosystem productivity. Thus, R+ was associated with persistence in ecosystems characterised by higher productivity and relatively frequent surface fires of moderate to low severity (fire-productivity hypothesis). S+, the fire-stimulated recruitment by seed, occurred in ecosystems characterised by infrequent but intense crown-fire and topkill, reducing competition between postfire survivors and recruits (fire-resource-competition hypothesis). Consistently large proportions of R+ or S+ imply fire has been a pervasive evolutionary selection pressure resulting in highly fire-adapted and fire-resilient flora in most Australian ecosystems.
AB - Postfire resprouting (R+) and recruitment from seed (S+) are common resilience traits in Australian ecosystems. We classified 2696 woody Australian taxa as R+ or not (R-) and as S+ or not (S-). The proportions of these traits in Australian ecosystems were examined in relation to fire regimes and other ecological correlates, and by trait mapping on a phylogeny scaled to time. Resprouting mapped as an ancestral trait. Postfire reseeding recruitment, while ancient, is more taxonomically restricted and has evolved independently several times. Nevertheless, both R+ and S+ are common in most clades, but negatively correlated at the ecosystem level indicating an evolutionary trade-off related to differences in the severity of fire regimes, determined in part by ecosystem productivity. Thus, R+ was associated with persistence in ecosystems characterised by higher productivity and relatively frequent surface fires of moderate to low severity (fire-productivity hypothesis). S+, the fire-stimulated recruitment by seed, occurred in ecosystems characterised by infrequent but intense crown-fire and topkill, reducing competition between postfire survivors and recruits (fire-resource-competition hypothesis). Consistently large proportions of R+ or S+ imply fire has been a pervasive evolutionary selection pressure resulting in highly fire-adapted and fire-resilient flora in most Australian ecosystems.
KW - crown fire regime
KW - ecosystem productivity
KW - fire-resilient flora
KW - fire-stimulated recruitment
KW - persistence niche
KW - postfire reseeding
KW - postfire resprouting
KW - surface fire regime
UR - http://www.scopus.com/inward/record.url?scp=85126220261&partnerID=8YFLogxK
U2 - 10.1071/BT21110
DO - 10.1071/BT21110
M3 - Article
SN - 0067-1924
VL - 70
SP - 114
EP - 130
JO - Australian Journal of Botany
JF - Australian Journal of Botany
IS - 2
ER -